Ultrasound marker detection, markers and associated systems, methods and articles

ABSTRACT

Markers for use in bodily tissue take a variety of forms, and may include a plurality of ultrasound reflective elements, for example hollow shells filled with air, and a hydrogel that binds the ultrasound reflective elements. The hydrogel may be natural or artificial and may be cross-linked. An ultrasound system advantageously injects variance in a drive signal, that varies a frequency or phase of an ultrasound interrogation signal from a nominal frequency or nominal phase. The amount of variation is preferable one to six orders of magnitude less than the nominal frequency or phase. The ultrasound system can present or detect a twinkling artifact at least in a Doppler mode of operation, resulting from interaction of the varying interrogation signal with the ultrasound reflective elements.

FIELD

This disclosure generally relates to ultrasound detection of markers in bodily tissue, and further relates to markers, and associated systems, method articles of manufacture, and/or kits, which may, for example, facilitate detection of margins of bodily tissue (e.g., abnormal bodily tissue) to be monitored, biopsied, excised or ablated.

BACKGROUND Description of the Related Art

Various types of markers are used to mark bodily tissue that is to be monitored over time, or biopsied, excised or ablated. Some markers may, for example, allow or enhance visual detection by a surgeon. Some markers allow detection via various energy emitted imaging modalities, for example ultrasound imaging, radiological imaging such as X-ray imaging or magnetic resonance imaging (MRI). These different imaging modalities are often employed in different scenarios, and markers detectable under the various visual detecting or imaging modalities typically require different physical characteristics in order to be detectable.

Some markers may be permanent, while other markers may be absorbable by the body over a period of time. For example, it may be useful to mark a portion of bodily tissue for subsequent evaluation or detection over a fairly extended period (e.g., months, year).

There is a need for markers which are detectable via ultrasound, as well as additional imaging modalities, and which are optionally absorbable over time.

There is also a need for improved imaging techniques that do not employ ionizing radiation, for instance improved ultrasound imaging techniques that may enhance detection of markers in bodily tissue and/or detection of the margins of certain bodily tissues (e.g., abnormal bodily tissues, for instance tumors, or bodily tissues suspected of being abnormal).

BRIEF SUMMARY

This disclosure generally relates to ultrasound detection of markers in bodily tissue, and further relates to detectable markers, and associated systems, method, articles of manufacture, and/or kits which may, for example, facilitate more precise detection of tissue to be monitored, biopsied, excised or ablated than otherwise possible using conventional approaches.

Markers for use in bodily tissue take a variety of forms, and may include a plurality of ultrasound reflective elements and a hydrogel that binds the ultrasound reflective elements. The ultrasound reflective elements may, for example, take the form of hollow shells. Cavities of the hollow shells may be filled with a fluid, for example a gas such air, a liquid, or a combination of gas and liquid (e.g., a vapor) and may advantageously be devoid of perfluorocarbon. The hollow shells may be porous, and may be coated with a hydrophobic coating to at least temporally seal the pores to prevent or delay the release of fluid (e.g., gas) from the cavities to an exterior of the hollow shells. The ultrasound reflective elements may comprise or consist of silica in one or more forms. The hydrogel may be a natural, for instance gelatin, or an artificial hydrogel, for instance polyethylene glycol (PEG). The hydrogel may be partially or fully cross-linked. The hydrogel may be engineered to be absorbed by the body over a period of time, or alternatively may be non-absorbable.

An ultrasound system advantageously injects variance in a drive signal, that varies a frequency or phase of an ultrasound interrogation signal from a nominal frequency or nominal phase. The amount of variation is preferable one to six orders of magnitude less than the nominal frequency or phase. The variance may be periodic, may form of follow a defined pattern, or may be pseudo-random or random. The ultrasound system can present or detect a twinkling artifact at least in a Doppler mode of operation, resulting from interaction of the varying interrogation signal with the ultrasound reflective elements.

The markers and the ultrasound system may be provided as a kit, the hollow shell ultrasound reflective elements being particular effective at producing a twinkling artifact when subjected to an ultrasound interrogation signal with a variance in frequency or phase, preferably in a range of one to six orders of magnitude less than a nominal frequency or phase, during Doppler mode operation.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

In the drawings, identical reference numbers identify similar elements or acts. The sizes and relative positions of elements in the drawings are not necessarily drawn to scale. For example, the shapes of various elements and angles are not drawn to scale, and some of these elements are arbitrarily enlarged and positioned to improve drawing legibility. Further, the particular shapes of the elements as drawn, are not intended to convey any information regarding the actual shape of the particular elements, and have been solely selected for ease of recognition in the drawings.

FIG. 1 is an isometric view of a marker to mark bodily tissue according to one illustrated implementation, the marker comprising a plurality of ultrasound reflective elements and a hydrogel carrier, with an enlarged view showing one of the ultrasound reflective elements in detail including a contrast agent carried by the ultrasound reflective element to enhance detection for in other imaging modalities.

FIG. 2 is an isometric view of a marker to mark bodily tissue according to one illustrated implementation, the marker comprising a plurality of ultrasound reflective elements, a hydrogel, and an optional wire, with an enlarged view showing one of the ultrasound reflective elements in detail including contrast agents carried by the ultrasound reflective element to enhance detection for in other imaging modalities, as well as a hydrophobic coating.

FIG. 3 is a schematic view of an analog pulse ultrasound imaging system according to at least one illustrated implementation, the analog pulse ultrasound imaging system which introduces a variation from a nominal pulse repetition frequency into a drive signal that drives an ultrasound transducer, and which is operable to detect, in a Doppler mode (e.g., color Doppler mode) of operation, a twinkling artifact in the received return signal, the twinkling artifact resulting from interaction of the ultrasound signal having the varied pulse repetition frequency with at least a portion of a marker that is ultrasound reflective and which preferably has an irregular surface.

FIG. 4 is a schematic view of a digital pulse ultrasound imaging system according to at least one illustrated implementation, the digital pulse ultrasound imaging system which introduces a variation from a nominal pulse repetition frequency into a drive signal that drives an ultrasound transducer, and which is operable to detect, in a Doppler mode (e.g., color Doppler mode) of operation, a twinkling artifact in the received return signal, the twinkling artifact resulting from interaction of the ultrasound signal having the varied pulse repetition frequency with at least a portion of a marker that is ultrasound reflective and which preferably has an irregular surface.

FIG. 5 is a schematic view of a continuous wave (CW) ultrasound imaging system according to at least one illustrated implementation, the CW ultrasound imaging system which introduces a variation from a nominal pulse repetition frequency into a drive signal that drives an ultrasound transducer, and which is operable to detect, in a Doppler mode (e.g., color Doppler mode) of operation, a twinkling artifact in the received return signal, the twinkling artifact resulting from interaction of the ultrasound signal having the varied pulse repetition frequency with at least a portion of a marker that is ultrasound reflective and which preferably has an irregular surface.

FIG. 6 is a block diagram of a signal processing algorithm which can be implemented in hardware, software and/or firmware, according to at least one illustrated implementation.

FIG. 7A is a graph showing an exemplary raw analog-to-digital (ADC) signal in a time domain produced by an ADC, according to at least one illustrated implementation.

FIG. 7B is a graph showing an exemplary raw analog-to-digital (ADC) signal in a frequency domain produced by an ADC, according to at least one illustrated implementation.

FIG. 8A is a graph showing an exemplary band-pass filtered ADC signal in the time domain after band-pass filtering the raw ADC signal, according to at least one illustrated implementation.

FIG. 8B is a graph showing an exemplary band-pass filtered ADC signal in the frequency domain after band-pass filtering the raw ADC signal, according to at least one illustrated implementation.

FIG. 9 is a graph showing a filter response for an exemplary band pass filter, according to at least one illustrated implementation.

FIG. 10A is a graph showing an I/Q signal in a time domain output by an I/Q mixer after mixing with an I/Q reference signal, according to at least one illustrated implementation.

FIG. 10B is a graph showing an I/Q signal in the frequency domain output by an I/Q mixer after mixing with an I/Q reference signal, according to at least one illustrated implementation.

FIG. 11A is a graph showing a low passed filtered I/Q signal in the time domain output by the low pass filter, according to at least one illustrated implementation.

FIG. 11B is a graph showing a low passed filtered I/Q signal in the frequency domain output by the low pass filter, according to at least one illustrated implementation.

FIG. 12 is a graph showing a filter response of an exemplary low-pass filter that, for example, selects frequencies less than 1 MHz, according to at least one illustrated implementation.

FIG. 13A is a graph showing a down sampled I/Q signal in the time domain, output by the down sampler, according to at least one illustrated implementation.

FIG. 13B is a graph showing a down sampled I/Q signal in the frequency domain, output by the down sampler, according to at least one illustrated implementation.

FIG. 14A is a graph showing down sampled I/Q data that results from the down sampling, according to at least one illustrated implementation.

FIG. 14B is a graph showing a phase in degrees of the down sampled I/Q data, according to at least one illustrated implementation.

FIG. 14C is a graph showing a normalized amplitude of the down sampled I/Q data, according to at least one illustrated implementation.

DETAILED DESCRIPTION

In the following description, certain specific details are set forth in order to provide a thorough understanding of various disclosed embodiments. However, one skilled in the relevant art will recognize that embodiments may be practiced without one or more of these specific details, or with other methods, components, materials, etc. In other instances, well-known structures associated with microcontrollers, piezo-electric devices or transducers, power supplies such as DC/DC converters, wireless radios (i.e., transmitters, receivers or transceivers), computing systems including client and server computing systems, and networks (e.g., cellular, packet switched), as well as other communications channels, have not been shown or described in detail to avoid unnecessarily obscuring descriptions of the embodiments.

Unless the context requires otherwise, throughout the specification and claims which follow, the word “comprise” and variations thereof, such as, “comprises” and “comprising” are to be construed in an open, inclusive sense, that is, as “including, but not limited to.”

Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, the appearances of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” include plural referents unless the content clearly dictates otherwise. It should also be noted that the term “or” is generally employed in its sense including “and/or” unless the content clearly dictates otherwise.

The headings and Abstract of the Disclosure provided herein are for convenience only and do not interpret the scope or meaning of the embodiments.

In particular, described herein are new tissue markers and ultrasound techniques, systems, methods, and articles of manufacture to advantageously mark tissue for later evaluation, excision, and/or ablation. Such may, for example, be used to more precisely define the margins of abnormal or suspect tissue (e.g., a tumor) in bodily tissue.

FIG. 1 shows a marker 100 to mark bodily tissue, according to at least one illustrated implementation.

In at least one implementation, the marker 100 comprises a plurality of ultrasound reflective elements 102 (only one called out) carried by the hydrogel carrier 104. The hydrogel carrier 104 binds the plurality of ultrasound reflective elements 102 together.

The hydrogel carrier 104 may take variety of forms. The hydrogel carrier 104 may comprise a natural hydrogel, for example a gelatin. The hydrogel carrier 104 may comprise an artificial hydrogel, for example a polyvinyl alcohol (PVA) hydrogel or a polyethylene glycol (PEG) hydrogel. The hydrogel carrier 104 may comprise a combination of a natural hydrogel (e.g., gelatin) and an artificial hydrogel (e.g., PVA hydrogel, PEG hydrogel).

In at least some of the implementations, the hydrogel carrier 104 is an at least partially cross-linked hydrogel. In at least some of the implementations, the hydrogel carrier 104 is a gelatin, for example a cross-linked gelatin. In at least some of the implementations, the hydrogel carrier 104 is a PVA hydrogel, for example a cross-linked PVA hydrogel. In at least some of the implementations, the hydrogel carrier 104 is a PEG hydrogel, for example a cross-linked PEG hydrogel. In at least some of the implementations, the hydrogel carrier 104 comprises a combination of a natural hydrogel and an artificial hydrogel, for instance as respective gel bodies coupled to one another.

The hydrogel carrier 104 may be non-absorbable by the body (e.g., persistent over 60 years or longer), or may be absorbable by the body within of a period of time. Where absorbable, the hydrogel carrier 104 may be engineered (e.g., via extent or strength of cross-linking) to persist in the body for a period of time, for example being persistent over a period of hours, days, a week or weeks, a month or months, or even for a year or years. In at least some implementations, outer or exposed portions of an absorbable hydrogel carrier 104 when implanted may absorb sooner than more interior portions of the hydrogel carrier, the absorption occurring as various portions of the hydrogel carrier 104 are exposed to bodily tissue, including bodily fluids. In at least some implementations, the hydrogel carrier 104 can be engineered (e.g., controlled cross-linking profiles) to cause some portions to absorb faster than other portions and/or to ensure that some portions persist longer than other portions. Thus, various absorption profiles may be formed across or through a hydrogel carrier.

Each ultrasound reflective element is highly reflective of ultrasound. Each ultrasound reflective element preferably has in irregular surface, for example having a rough outer surface to cause scattering or dispersion of ultrasound energy. The ultrasound reflective elements 102 may be in the nanometer size range (e.g., 1.8 microns to about 2.2 microns).

The ultrasound reflective elements 102 may take any of a large variety of forms.

In at least one implementation, each ultrasound reflective element comprises a particle that is not a hollow shell, but which is a solid particle or alternatively a porous non-spherical particle. Each ultrasound reflective element may, for example, comprise a respective particle that comprises, or consists of, silica without a hollow interior cavity. Each particle may comprise one or more layers (not shown in FIG. 1 ). The one or more layers may including contrast agents 106, to enhance detection via modalities other than ultrasound imaging, as discussed below. Alternatively, one or more ultrasound reflective elements may comprise, or consist of, one or more contrast agents.

Contrast agents 106 may, for example include one or more contrast agents that enhance visual detection, or detection using X-ray or MRI imaging modalities. For example, some or all of the ultrasound reflective elements 102 may include a dye to enhance detection by direct visual observation. The dye may advantageously be a florescent dye. The dye may, for example, comprise or consist of methylene blue. Also for example, some or all of the ultrasound reflective elements 102 may include or consist of a radiopaque material (e.g., gold, platinum, tantalum, bismuth, barium and the like). Also for example, some or all of the ultrasound reflective elements 102 may include or consist of an MRI imaging material (e.g., as gadolinium including compounds such as gadolinium DTPA, ferrous gluconate, ferrous sulfate and the like).

Alternatively, one or more contrast agents 106, for example the contrast agents 106 identified above or a wire (e.g., helical wound metal wire) or other radiopaque element such as a radiopaque clip, may be incorporated into or about the hydrogel carrier 104, in addition to the ultrasound reflective elements 102.

In at least one implementation, each ultrasound reflective element 102 comprises a hollow shell. Each hollow shell has at least one outer wall that forms a cavity. In at least some implementations, the hollow shell is a multi-layer hollow shell, for example a shell with an inner layer and an outer layer. Each hollow shell is highly reflective of ultrasound. Each hollow shell preferably has in irregular surface, for example having a rough outer surface to cause scattering or dispersion of ultrasound energy. The hollow shells may be in the nanometer size range.

In at least some implementations, each hollow shell may comprise, or alternatively consist of, a silica or titanium dioxide. Some techniques to form hollow shells in the nanometer size range are described, for example in: U.S. patent application 60/955,678; U.S. patent application 61/034,468; U.S. patent application Ser. No. 12/673,224 (now U.S. Pat. No. 8,440,229); International patent application PCT/US2008/072972; U.S. patent application Ser. No. 13/866,940 (now U.S. Pat. No. 9,220,685); U.S. patent application Ser. No. 15/722,436; U.S. patent application 61/707,794; International patent application PCT/US2013/062436; U.S. patent application Ser. No. 15/706,446; U.S. patent application 62/135,653; U.S. patent application Ser. No. 15/559,764; International patent application PCT/US2016/23492; U.S. patent application 62/483,274; U.S. patent application 62/645,677; U.S. patent application Ser. No. 15/946,479; and International patent application PCT/US2018/26291.

The hollow shells, or one or more layers of the hollow shell may comprise one or more contrast agents, for example the contrast agents identified above to enhance visual, radiological or MRI detection.

In at least some implementations, the cavity of the at least one hollow shell contains a fluid, that is a gas, a liquid, or a combination or mixture of a gas and a liquid. The gas may take the form of one material while the liquid takes the form of another material, different from the material that forms the gas. Alternatively, the gas and liquid may be the same material, just in different phase states. The combination or mixture of gas and liquid may, for instance, take the form of a vapor, either in a quiescent state or when subjected to ultrasound at some threshold level of energy which causes heating. The cavity of the at least one hollow shell may, for example, contain air. Alternatively, the cavity of the at least one hollow shell may contain an inert gas (e.g., nitrogen, argon). The cavity is preferably devoid of any perfluorocarbon, for instance whether in either gaseous and/or liquid forms.

Each hollow shell may be porous. Where the hollow shell contains a fluid (i.e., gas, liquid, or combination or mix of gas and liquid), the marker 100 may optionally include comprise a coating, preferably a hydrophobic coating, that at least temporarily seals one or more pores thereof.

In some implementations, the hydrogel may be expandable, for example when implanted into bodily tissue. In some implementations the marker 100 may, in an unexpanded state, have a length of about 2 mm to about 40 mm and a transverse dimension of about 0.5 mm to about 2 mm. The marker may have a ratio of size expansion from a dried unexpanded state to a water saturated expanded state of about 1:1.5 to about 1:10. The marker 100 may have a ratio of size expansion from a dried unexpanded state to a water saturated expanded state of about 1:2 to about 1:3.

FIG. 2 shows a marker 200 to mark bodily tissue, according to at least one illustrated implementation.

In at least one implementation, the marker 200 comprises at least one hollow shell 202, and preferably a plurality of hollow shells 202 (only one called out). Each hollow shell 202 has at least one outer wall that forms a cavity. In at least some implementations, the hollow shell 202 is a multi-layer hollow shell, for example a shell with an outer layer 202 a, an inner layer 202 b, and a cavity 202 c. Each hollow shell 202 is highly reflective of ultrasound. Each hollow shell 202 preferably has in irregular surface, for example having a rough outer surface to cause scattering or dispersion of ultrasound energy. The hollow shells 202 may be in the nanometer size range (e.g., 1.8 microns to about 2.2 microns).

In at least some implementations, each hollow shell 202 may comprise, or alternatively consist of, a silica or titanium dioxide. Some techniques to form hollow shells 202 in the nanometer size range are described, for example in: U.S. patent application 60/955,678; U.S. patent application 61/034,468; U.S. patent application Ser. No. 12/673,224 (now U.S. Pat. No. 8,440,229); International patent application PCT/US2008/072972; U.S. patent application Ser. No. 13/866,940 (now U.S. Pat. No. 9,220,685); U.S. patent application Ser. No. 15/722,436; U.S. patent application 61/707,794; International patent application PCT/US2013/062436; U.S. patent application Ser. No. 15/706,446; U.S. patent application 62/135,653; U.S. patent application Ser. No. 15/559,764; International patent application PCT/US2016/23492; U.S. patent application 62/483,274; U.S. patent application 62/645,677; U.S. patent application Ser. No. 15/946,479; and International patent application PCT/US2018/26291 (published as WO 2018/187594.

In at least some implementations, the cavity 202 c of the at least one hollow shell 202 contains a fluid, or a gas, or a combination or mixture of fluid(s) and gas(es). For example, the cavity 202 c of the at least one hollow shell may contain air. Alternatively, the cavity 202 c of the at least one hollow shell 202 may contain an inert gas (e.g., nitrogen, argon). The cavity 202 c is preferably devoid of any perfluorocarbon, for instance whether in either gaseous and/or liquid forms.

Each hollow shell 202 may be porous. Where the hollow shell 202 contains a fluid (i.e., gas(es), liquid(s), or mix of gas(es) and liquid(s)), the marker 200 may optionally include comprise a coating, preferably a hydrophobic coating 208, that at least temporarily seals one or more pores thereof. The hydrophobic coating 208 may take the form of a hydrophobic polymer, for example a hydrophobic polymer that comprises octyltriethoxysilane.

One or more layers 202 a, 202 b of the hollow shell 202 may comprise one or more contrast agents 206 a, 206 b, to enhance detection via modalities other than ultrasound imaging, as discussed below.

Contrast agents may, for example include one or more contrast agents that enhance visual detection, or detection using X-ray or MRI imaging modalities. For example, some or all of the ultrasound reflective elements 102 may include a dye 206 a (in outer most layer 202 a) to enhance detection by direct visual observation. The dye may advantageously be a florescent dye. The dye may, for example, comprise or consist of methylene blue. Also for example, some or all of the ultrasound reflective elements 102 may include or consist of a radiopaque material (e.g., gold, platinum, tantalum, bismuth, barium and the like) and/or an MRI imaging material (e.g., as gadolinium including compounds such as gadolinium DTPA, ferrous gluconate, ferrous sulfate and the like) collectively 202 b.

As noted above, the marker 200 may preferably comprise a plurality of hollow shells 202. The marker 200 may further comprise a hydrogel 204 that binds the plurality of hollow shells 202 together. In at least some of the implementations, the hydrogel 204 is an at least partially cross-linked hydrogel. In at least some of the implementations, the hydrogel 204 is a gelatin, for example a cross-linked gelatin. The hydrogel 204 may take variety of forms. For example, the hydrogel may be a natural hydrogel (e.g., gelatin) or an artificial hydrogel (e.g., polyvinyl alcohol (PVA) hydrogel, polyethylene glycol (PEG) hydrogel). The hydrogel 204 may be non-absorbable by the body (e.g., persistent over 60 years or longer), or may be absorbable by the body within of a period of time. Where absorbable, the hydrogel 204 may be engineered (e.g., via extent or strength of cross-linking) to persist in the body for a period of time, for example being persistent over a period of hours, days, a week or weeks, a month or months, or even for a year or years. In at least some implementations, outer or exposed portions of an absorbable hydrogel when implanted may absorb sooner than more interior portions of the hydrogel, the absorption occurring as various portions of the hydrogel are exposed to bodily tissue, including bodily fluids. In at least some implementations, the hydrogels 204 can be engineered (e.g., controlled cross-linking profiles) to cause some portions to absorb faster than other portions and/or to ensure that some portions persist longer than other portions. Thus, various absorption profiles may be formed across or through a hydrogel 204.

One or more contrast agents 206 a, 206 b, for example the contrast agents identified above or a radiopaque element (e.g., radiopaque wire, helical wound metal wire 210, radiopaque clip), may be incorporated into or about the hydrogel carrier, in addition to the hollow shells 202.

In some implementations, the hydrogel may be expandable, for example when implanted into bodily tissue. In some implementations the marker 200 may, in an unexpanded state, have a length of about 2 mm to about 40 mm and a transverse dimension of about 0.5 mm to about 2 mm. The marker may have a ratio of size expansion from a dried unexpanded state to a water saturated expanded state of about 1:1.5 to about 1:10. The marker 200 may have a ratio of size expansion from a dried unexpanded state to a water saturated expanded state of about 1:2 to about 1:3.

FIG. 3 shows a marker 300 implanted in bodily tissue 302, and an analog pulse Doppler ultrasound system 304 including an ultrasound probe or transducer array 306 positioned to detect the marker 300, according to at least one illustrated embodiment.

The analog pulse Doppler ultrasound system 304 includes a transmit section 308 and a receive section 310. The transmit section 308 generates pulses and drives the ultrasound probe or transducer array 306 to emit ultrasound energy. The receive section 310 receives signals representative of the ultrasound energy returned from objects in the field of view of the ultrasound probe or transducer array 306, and processes the return signals based on one or more operational modes (e.g., A-mode, B-mode, M-mode, Doppler color mode, Doppler power mode). In some implementations, the analog pulse Doppler ultrasound system 304 will alternate between capturing B-mode frames and Doppler color or power mode frames, for example with the variation in the pulse repetition occurring during Doppler mode operation but not occurring during B-mode operation.

The analog pulse Doppler ultrasound system 304 includes a master clock or oscillator 312 which outputs a timing signal. The timing signal output by the master clock or oscillator 312 sets or is used to set a nominal pulse repetition frequency, that is the frequency at which ultrasound pulses repeat. In at least some implementations, the nominal pulse repetition frequency can be set by an operator, at least within some defined range. In other implementations, the nominal pulse repetition frequency may be a fixed characteristic of the particular analog pulse Doppler ultrasound system 304.

The transmit section 308 includes a variation circuit (VAR) 314 that introduces a variation in the clock signal provided by the master clock or oscillator 312, either directly or indirectly (e.g., via gate generator) introducing a variation from the nominal pulse repetition frequency into the drive signal used to drive the ultrasound probe or transducer array 306 during a Doppler mode operation. The variation may be a variation in time or a variation in phase, and the variation is a variation over a period of time. The variation may, for example, be implemented via one or more delay circuits or capacitors, which delay the clock signal. For example, a delay circuit may have an adjustable delay, or two or more different delay circuits, each with respective delays, may introduce delays of different durations to achieve the variation during the Doppler mode operation. The variation may be periodic, may follow a pattern, or may be pseudo-random, for instance produced via a pseudo-random number generator, also known as a random number generator (RNG). A periodic variation may have a period or frequency that is different from the nominal pulse repetition frequency. A periodic variation or variation that follows a pattern may be advantageously employed by the receive section 310. The variation may be introduced into the drive signal over a plurality of pulses emitted during a Doppler mode of operation during capture of one or more Doppler frames of ultrasound data to intentionally introduce an artifact that would typically be considered undesirable noise.

The variation is preferably at least one order of magnitude less than the nominal pulse repetition frequency, and more preferably two orders of magnitude, three orders of magnitude, four orders of magnitude, five orders of magnitude, or most preferably six orders of magnitude less than the nominal pulse repetition frequency.

The varied clock signal is supplied to a gate generator 316, which is communicatively coupled via an amplifier 318 to drive the ultrasound probe or transducer array 306. The varied clock signal is also supplied to the receive section 310, for example to a set of mixers 320, and a set delay and duration circuit 322. The set delay duration circuit 322 is communicatively coupled to a second set of mixers 324 of the receive section 310, which feed a set of range gates 326, which in turn feed a set of hold and filter circuits 328 of the receive section 310.

The receive section 310 receives signals representative of the ultrasound energy returned from objects in the field of view of the ultrasound probe or transducer array 306, and an amplifier 330 of the receive section 310 amplifies the return signals. A matched filter 332 filters the amplified return signals. The set of mixers 320 then mix in the varied clock signal, and the results are low pass filtered by a set of low pass filters 334 to provide for quadrature processing, via second set of mixers 324, range gates 326, and hold and filter circuits 328.

FIG. 4 shows a marker 400 implanted in bodily tissue 402, and a digital pulse Doppler ultrasound system 404 include an ultrasound probe 406 positioned to detect the marker 400, according to at least one illustrated implementation.

The digital pulse Doppler ultrasound system 404 includes a transmit section 408 and a receive section 410. The transmit section 408 generates pulses and drives the ultrasound probe or transducer array 406 to emit ultrasound energy. The receive section 410 receives signals representative of the ultrasound energy returned from objects in the field of view of the ultrasound probe or transducer array 406, and processes the return signals based on one or more operational modes (e.g., A-mode, B-mode, M-mode, Doppler color mode, Doppler power mode). In some implementations, the digital pulse Doppler ultrasound system 404 will alternate between capturing B-mode frames and Doppler color or power mode frames, for example with the variation in the pulse repetition occurring during Doppler mode operation but not occurring during B-mode operation.

The digital pulse Doppler ultrasound system 404 includes a master clock or oscillator 412 which outputs a timing signal. The timing signal output by the master clock or oscillator 412 sets or is used to set a nominal pulse repetition frequency, that is the frequency at which ultrasound pulses repeat. In some implementations, the nominal pulse repetition frequency can be set by an operator, at least within some defined range. In other implementations, the nominal pulse repetition frequency may be a fixed characteristic of the particular digital pulse Doppler ultrasound system 404.

The transmit section 408 includes a variation circuit (VAR) 414 that introduces a variation in the clock signal provided by the master clock or oscillator 412, either directly or indirectly (e.g., via gate generator) introducing a variation from the nominal pulse repetition frequency into the drive signal used to drive the an ultrasound probe or transducer array 406 during a Doppler mode operation. The variation may be a variation in time or a variation in phase, and the variation is a variation over a period of time during the Doppler mode operation. The variation may, for example, be implemented via one or more delay circuits, which delay the clock signal. For example, a delay circuit may have an adjustable delay, or two or more different delay circuits, each with respective delays, may introduce delays of different durations to achieve the variation. The variation may be periodic, may follow a pattern, or may be pseudo-random, for instance produced via a pseudo-random number generator, also known as a random number generator (RNG). A periodic variation may have a period or frequency that is different from the nominal pulse repetition frequency. A periodic variation or variation that follows a pattern may be advantageously employed by the receive section 410. The variation is preferably at least one order of magnitude less than the nominal pulse repetition frequency, and more preferably two orders of magnitude, three orders of magnitude, four orders of magnitude, five orders of magnitude, or most preferably six orders of magnitude less than the nominal pulse repetition frequency.

The varied clock signal is supplied to a gate generator 416, which is communicatively coupled via an amplifier 418 to drive the ultrasound probe or transducer array 406. The varied clock signal is also supplied to the receive section 410, for example to a set of mixers 420, and a set of analog-to-digital converters (ADCs) 422.

The receive section 410 receives signals representative of the ultrasound energy returned from objects in the field of view of the ultrasound probe or transducer array 406, and an amplifier 424 of the receive section 410 amplifies the return signals. A matched filter 426 filters the amplified return signals. The set of mixers 420 then mix in the varied clock signal, and the results are analog-to-digital converted by ADCs 422. The output from the ADCs 422 are provided to a set of range gates 428 for digital signal processing.

FIG. 5 shows a marker 500 implanted in bodily tissue 502, and a continuous wave Doppler ultrasound system 504 including an ultrasound probe or transducer array 506 positioned to detect the marker 500, according to at least one illustrated embodiment.

The continuous wave Doppler ultrasound system 504 includes a transmit section 508 and a receive section 510. The transmit section 508 generates a continuous (e.g., sine wave, cosine wave) signal and drives the ultrasound probe or transducer array 506 to emit ultrasound energy. The receive section 510 receives signals representative of the ultrasound energy returned from objects in the field of view of the ultrasound probe or transducer array 506, and processes the return signals based on one or more operational modes (e.g., A-mode, B-mode, M-mode, Doppler color mode, Doppler power mode). In some implementations, the continuous wave Doppler ultrasound system 504 will alternate between capturing B-mode frames and Doppler color or power mode frames, for example with the variation in the pulse repetition occurring during Doppler mode operation but not occurring during B-mode operation.

The continuous wave Doppler ultrasound system 504 includes a master clock or oscillator 512 which outputs a timing signal. The timing signal output by the master clock or oscillator 512 sets or is used to generate the continuous wave (e.g., sine wave, cosine wave). In some implementations, a frequency of the continuous wave can be set by an operator, at least within some defined range. In other implementations, the frequency of the continuous wave may be a fixed characteristic of the particular ultrasound system 504.

The transmit section 508 includes a variation circuit (VAR) 514 that introduces a variation in the continuous wave signal provided by the master clock or oscillator 512, either directly or indirectly introducing a variation from a nominal frequency of the continuous wave drive signal used to drive the ultrasound probe or transducer array 506 during a Doppler mode operation. The variation may be represented as a variation in time or a variation in phase, and the variation is a variation over a period of time during the Doppler mode operation. The variation may, for example, be implemented via one or more delay circuits, which delay the clock signal. For example, a delay circuit may have an adjustable delay, or two or more different delay circuits, each with respective delays, may introduce delays of different durations to achieve the variation. The variation may be periodic, may follow a pattern, or may be pseudo-random, for instance produced via a pseudo-random number generator, also known as a random number generator (RNG). A periodic variation may have a period or frequency that is different from the nominal pulse repetition frequency. A periodic variation or variation that follows a pattern may be advantageously employed by the receive section 510. The variation is preferably at least one order of magnitude less than the nominal pulse repetition frequency, and more preferably two orders of magnitude, three orders of magnitude, four orders of magnitude, five orders of magnitude, or most preferably six orders of magnitude less than the nominal pulse repetition frequency.

The varied continuous wave signal is also supplied to the receive section 510, for example to a set of mixers 520, which may be implemented in hardware, software and/or firmware.

The receive section 510 receives signals representative of the ultrasound energy returned from objects in the field of view of the ultrasound probe or transducer array 506, and an amplifier 530 of the receive section 510 amplifies the return signals. A matched filter 532 filters the amplified return signals. The set of mixers 520 then mix in the varied continuous wave signal, and the results are low pass filtered by a set of low pass filters 534. A phase shifter 535 phase shifts one of the signal paths, to provide for quadrature processing, and a set of summers 537 produce separated Doppler outputs (e.g., forward flow; reverse flow).

In any of the implementations of FIGS. 3, 4 and 5 , an image captured during Doppler mode operation may be presented superimposed with an image captured during B-mode operation to facilitate visualization of the maker with respect to various anatomical features of the body.

FIG. 6 shows a signal processing algorithm 600 which can be implemented in hardware, software and/or firmware, according to at least one illustrated implementation. The hardware may, for example include an analog-to-digital converter (ADC), field programmable gate array (FPGA), and one or more processor based computer systems that employs one or more processors and memory or other non-transitory storage media. The processor(s) may, for example, include one or more of: microprocessors, microcontrollers, central processing units (CPUs), digital signal processors (DSPs), graphics processing units (GPUs), applications specific integrated circuits (ASICs), field programmable gate arrays (FPGAs), and/or programmed logic controllers (PLCs), etc. The memory may, for example, include one or more of: read only memory (ROM), random access memory (RAM), EEPROMs, Flash memory, and/or registers, etc. The other non-transitory storage media may, for example, include one or more of: magnetic disks and associated magnetic disk drives, optical disks and associated optical disk drives, and/or solid state drives (SSDs), etc.

An analog transducer signal 602 is received from a transducer (not shown in FIG. 6 ). The received analog transducer signal 602 has a center frequency, for example a center frequency of 3 MHz.

The received analog transducer signal 602 is digitized, for example via an ADC 604. The ADC 604 may, for example take the form of a 14-Bit ADC with, for example, a 12 MHz sample clock 605.

The raw ADC sample data output by the ADC 604 is captured by an FPGA 606 (add FIG. 6 ), and transferred to a processor-based computer system (represented by broken-line box) 608, for example via a USB interface 610. Notably, the FPGA 606 just captures the ADC sample data and passes the ADC sample data to the processor-based computer system 608 without performing any operations on the ADC sample data.

FIGS. 7A and 7B illustrate an example of the raw ADC signals 700 a, 700 b in time and frequency domains, respectively. In particular, FIG. 7A is zoomed in on the raw ADC signal 700 a from a 750th to 850th sample. FIG. 7B is a power spectral density estimate of the raw ADC signals 700 b which is based on FFT. One can see how the maximum power is centered about 3 MHz, which is expected given that the Tx frequency is 3 MHz. At this point, the raw ADC signal has not been filtered.

Returning to FIG. 6 , the processor-based computer system 608 may perform the remaining signal processing operations. For example, software written in Python may operate on the collected raw ADC samples provided via the FPGA 606.

In a first signal processing operation, the software executed by the processor-based computer system 608 may implement a band pass filter 612 to remove out-of-band noise before an I/Q Demodulation signal processing operation. The band pass filter 612 may, for example, have a pass band between 2 MHz to 4 MHz.

FIG. 8A illustrates a band-pass filtered ADC signal in the time domain 800 a (limited to time samples 750 and 850 out of a total of 1600 taken) after band-pass filtering the raw ADC signal (FIG. 7A) for 2-4 MHz. FIG. 8B shows a band-passed filtered ADC signal in frequency domain 800 b after band-pass filtering the raw ADC signal (FIG. 7B) for 2-4 MHz. Note how the frequency power in the range 0-2 and 4-6 MHz are greatly reduced when compared to that illustrated in FIGS. 7A and 7B.

FIG. 9 shows the filter response 900 for an exemplary band pass filter 612.

Returning to FIG. 6 , the software executed by the processor-based computer system 608 may implement an I/Q mixer 614 to perform demodulation signal processing operations. The I/Q mixer 614 mixes the output of the band pass filter 612 with an I/Q reference signal, for example a 3 MHz I/Q reference signal 615. The frequency of the I/Q reference signal 615 may preferably be matched to a center frequency of the received transducer signal 602.

FIG. 10A shows an I/Q signal 1000 a in the time domain output by the I/Q mixer 614 after mixing with an I/Q reference signal, containing the signal from the 750^(th) to 850^(th) sample. FIG. 10B shows a I/Q signal 1000 b in the frequency domain output by the I/Q mixer 614 after mixing with an I/Q reference signal. The mixed I/Q signal is centered around zero since the I/Q reference signal matches the frequency of the received signal. Notably, there is a very slight asymmetry between negative and positive frequencies.

Returning to FIG. 6 , the software executed by the processor-based computer system 608 may implement a low pass filter 616 to remove any double frequency components from the signal output by the I/Q Mixer 614, only keeping the baseband components. Applying a low pass filter obtains the envelope of the mixed signal. Notably, this is why the line in the time domain plot of FIG. 11A looks smooth unlike its counterpart in FIG. 10A). The low pass filter 616 may, for example, have a pass band set to 1 MHz.

FIG. 11A shows a low passed filtered I/Q signal 1100 a in the time domain output by the low pass filter 616.

FIG. 11B shows a low passed filtered I/Q signal 1100 b in the frequency domain output by the low pass filter 616.

FIG. 12 shows a filter 1200 response of an exemplary low-pass filter 616 that, for example, selects frequencies less than 1 MHz.

Returning to FIG. 6 , the software executed by the processor-based computer system 608 may implement a down sampler 618 in order to reduce the data sample rate. The down sampler 618 may reduce the data sample rate from, for example 12 MHz to 3 MHz, for instance where the data output from the low pass filter 616 only has frequency components less than 1 MHz. Reducing the sample rate advantageously reduces the amount of data required for processing without reducing the information content.

FIG. 13A shows the down sampled I/Q signal 1300 a in the time domain, output by the down sampler 618. FIG. 13B shows the down sampled I/Q signal 1300 b in the frequency domain, output by the down sampler 618. In the illustrated example, the low pass filtered I/Q data was advantageously down sampled by a factor of four.

Returning to FIG. 6 , the software executed by the processor-based computer system 608 may implement a phase computation component or signal processing operation 620, in which a phase of the down sampled I/Q signal is computed for each sample point for the down sampled I/Q data.

Returning to FIG. 6 , the software executed by the processor-based computer system 608 may implement an amplitude computation component or signal processing operation 622, in which an amplitude of the down sampled I/Q signal is computed for each sample point for the down sampled I/Q data.

FIG. 14A shows the down sampled I/Q data 1400 a that results from the down sampling. FIG. 14B shows a plot of the phase in degrees 1400 b of the down sampled I/Q data. FIG. 14C shows a plot of the normalized amplitude 1400c of the down sampled I/Q data. In this particular illustrated example, there is only a 10% range for amplitude and an approximately 1.5 degrees variation of phase.

EXAMPLES

Example 1. A method of operation in an ultrasound system, the method comprising:

generating a drive signal having a nominal pulse repetition frequency;

introducing a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal pulse repetition frequency;

supplying the drive signal with the introduced variation to the at least one ultrasound transducer to cause the at least one ultrasound transducer to emit the ultrasound signal having the variation from the nominal pulse repetition frequency;

emitting an ultrasound signal via at least one ultrasound transducer, the emitted ultrasound signal having a varied pulse repetition frequency, the varied pulse repetition frequency representing the variation from the nominal pulse repetition frequency; and

receiving a return signal via the at least one ultrasound transducer.

Example 2. The method of Example 1 wherein introducing the variation into the drive signal is in addition to any variation resulting from clock jitter, if any, of a master oscillator.

Example 3. The method of Example 2 wherein introducing the variation into the drive signal includes introducing a defined variation in pulse repetition frequency into the drive signal.

Example 4. The method of Example 3 wherein introducing a defined variation in pulse repetition frequency into the drive signal includes introducing a defined variation in pulse repetition frequency that changes over time in a defined pattern into the drive signal.

Example 5. The method of Example 2 wherein introducing the variation into the drive signal includes introducing a random variation in pulse repetition frequency into the drive signal.

Example 6. The method of Example 2 wherein introducing the variation into the drive signal includes introducing a delay into the drive signal by a delay circuit.

Example 7. The method of Example 1 wherein introducing a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal frequency includes introducing a variation from the nominal frequency into the drive signal, the variation being at least two orders of magnitude less than the nominal pulse repetition frequency.

Example 8. The method of Example 1 wherein introducing a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal frequency includes introducing a variation from the nominal frequency into the drive signal, the variation being at least three orders of magnitude less than the nominal pulse repetition frequency.

Example 9. The method of Example 1 wherein introducing a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal frequency includes introducing a variation from the nominal frequency into the drive signal, the variation being at least four orders of magnitude less than the nominal pulse repetition frequency.

Example 10. The method of Example 1 wherein introducing a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal frequency includes introducing a variation from the nominal frequency into the drive signal, the variation being at least five orders of magnitude less than the nominal pulse repetition frequency.

Example 11. The method of Example 1 wherein introducing a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal frequency includes introducing a variation from the nominal frequency into the drive signal, the variation being at least six orders of magnitude less than the nominal pulse repetition frequency.

Example 12. The method of any of Examples 1 through 11 wherein introducing a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal frequency includes introducing a variation from a nominal pulse repetition frequency into the drive signal.

Example 13. The method of any of Examples 1 through 11 wherein introducing a variation from the nominal frequency into the drive signal includes introducing a variation from a nominal pulse repetition frequency into the drive signal over a plurality of pulses emitted during a Doppler mode of operation during capture of one or more Doppler frames of ultrasound data.

Example 14. An ultrasound system, the comprising:

-   -   at least one ultrasound transducer;     -   a control system including at least one drive circuit, that in         operation:         -   generates a drive signal having a nominal pulse repetition             frequency;         -   introduces a variation from the nominal frequency into the             drive signal; and         -   causes the at least one ultrasound transducer to emit an             ultrasound signal having a varied pulse repetition             frequency, the varied pulse repetition frequency             representing the variation from the nominal pulse repetition             frequency.

Example 15. The ultrasound system of Example 14 wherein the variation introduced into the drive signal is in addition to any variation resulting from clock jitter, if any, of a master oscillator.

Example 16. The ultrasound system of Example 14 wherein to introduce the variation in pulse repetition frequency into the drive signal the control system introduces a defined variation in pulse repetition frequency into the drive signal.

Example 17. The ultrasound system of Example 14 wherein to introduce a defined variation in pulse repetition frequency into the drive signal the control system introduces a defined variation in pulse repetition frequency that changes over time in a defined pattern into the drive signal.

Example 18. The ultrasound system of Example 14 wherein to introduce the variation in pulse repetition frequency into the drive signal the control system introduces a random variation in pulse repetition frequency into the drive signal.

Example 19. The ultrasound system of Example 14 wherein to introduce the variation into the drive signal a delay circuit introduces a delay into the drive signal.

Example 20. The ultrasound system of Example 14 wherein to introduce a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal pulse repetition frequency, the control system introduces a variation from the nominal frequency into the drive signal, the variation at least two orders of magnitude less than the nominal pulse repetition frequency.

Example 21. The ultrasound system of Example 14 wherein to introduce a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal pulse repetition frequency, the control system introduces a variation from the nominal frequency into the drive signal, the variation at least three orders of magnitude less than the nominal pulse repetition frequency.

Example 22. The ultrasound system of Example 14 wherein to introduce a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal pulse repetition frequency, the control system introduces a variation from the nominal frequency into the drive signal, the variation in at least four orders of magnitude less than the nominal pulse repetition frequency.

Example 23. The ultrasound system of Example 14 wherein to introduce a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal pulse repetition frequency, the control system introduces a variation from the nominal frequency into the drive signal, the variation in at least five orders of magnitude less than the nominal pulse repetition frequency.

Example 24. The ultrasound system of Example 14 wherein to introduce a variation from the nominal frequency into the drive signal, the variation being at least one order of magnitude less than the nominal pulse repetition frequency, the control system introduces a variation from the nominal frequency into the drive signal, the variation in at least six orders of magnitude less than the nominal pulse repetition frequency.

Example 25. The ultrasound system of Example 14 wherein the at least one ultrasound transducer is coupled to the control system to provide signals to the control system, the signals representative of return signals received by the at least one ultrasound transducer, and the control system is operable to detect, in a color Doppler mode of operation, a twinkling artifact in the received return signal, the twinkling artifact resulting from interaction of the ultrasound signal having the varied pulse repetition frequency with at least a portion of a marker that is ultrasound reflective and has an irregular surface.

Example 26. The ultrasound system of any of Examples 14 through 23 wherein to introduce a variation from the nominal frequency into the drive signal the control system introduces a variation from a variation from a nominal pulse repetition frequency into the drive signal.

Example 27. The ultrasound system of any of Examples 14 through 23 wherein to introduce a variation from the nominal frequency into the drive signal the control system introduce a variation from a nominal pulse repetition frequency into the drive signal over a plurality of pulses emitted during a Doppler mode of operation during capture of a Doppler frame of ultrasound data.

Example 28. A method employing an ultrasound system, the method comprising:

-   -   directing an ultrasound signal toward a portion of bodily tissue         containing a marker, the ultrasound signal characterized by a         nominal pulse repetition frequency, and having an actual pulse         repetition frequency which varies over time from the nominal         pulse repetition frequency;     -   receiving a return signal from the portion of bodily tissue via         the at least one ultrasound transducer;     -   detecting a resonance of at least a portion of the marker         induced by the ultrasound signal in the received return signal         as a twinkling artifact in a color Doppler mode of operation of         the ultrasound system; and     -   localizing the marker in bodily tissue based at least in part on         the twinkling artifact in a color Doppler mode of operation.

Example 29. The method of Example 28, further comprising:

generating the ultrasound signal via at least one ultrasound transducer, the ultrasound signal having a nominal frequency over a period of time, the ultrasound signal further having a variation in pulse repetition frequency from the nominal pulse repetition frequency, the variation in frequency at least one or more orders of magnitude less than the nominal pulse repetition frequency.

Example 30. The method of Example 28, further comprising:

generating the ultrasound signal via at least one ultrasound transducer, the ultrasound signal having a nominal pulse repetition frequency over a period of time, the ultrasound signal further having a variation in pulse repetition frequency from the nominal pulse repetition frequency, the variation in frequency at least one or more orders of magnitude less than the nominal pulse repetition frequency.

Example 31. The method of Example 30 wherein generating the ultrasound signal includes:

generating a drive signal having the nominal pulse repetition frequency;

introducing the variation in frequency into the drive signal; and

supplying the drive signal with the introduced variation to the at least one ultrasound transducer to cause the at least one ultrasound transducer to emit the ultrasound signal having the variation in pulse repetition frequency from the nominal pulse repetition frequency.

Example 32. The method of Example 31 wherein introducing the variation in frequency into the drive signal includes introducing a variation from the nominal pulse repetition frequency into the drive signal over a plurality of pulses emitted during a Doppler mode of operation during capture of a Doppler frame of ultrasound data.

Example 33. The method of any of Examples 28 through 32 wherein directing an ultrasound signal toward a portion of bodily tissue containing a marker includes directing an ultrasound signal emitted by the at least one ultrasound transducer toward a portion of bodily tissue containing a marker, the maker comprising a hydrogel and a plurality of ultrasound reflective elements carried by the hydrogel.

Example 34. The method of any of Examples 28 through 32 wherein directing an ultrasound signal toward a portion of bodily tissue containing a marker includes directing an ultrasound signal toward a portion of bodily tissue containing a marker comprising an at least partially cross-linked hydrogel and a plurality of hollow shells at least temporarily encased by the at least partially cross-linked hydrogel, each of the hollow shells having a respective outer wall that forms a cavity, the outer wall having an irregular outer surface, and the cavity devoid of perfluorocarbon.

Example 35. A method of operation in an ultrasound system, the method comprising:

generating a drive signal via a master oscillator, the drive signal having a nominal pulse repetition frequency;

introducing a variation in a pulse repetition frequency of the drive signal with respect to the nominal pulse repetition frequency; and

driving at least one ultrasound transducer via the drive signal with the introduced variation in the pulse repetition frequency.

Example 36. The method of Example 35 wherein introducing the variation in pulse repetition frequency into the drive signal includes introducing a defined variation in pulse repetition frequency into the drive signal.

Example 37. The method of Example 35 wherein introducing a defined variation in pulse repetition frequency into the drive signal includes introducing a defined variation in pulse repetition frequency that changes over time in a defined pattern into the drive signal.

Example 38. The method of Example 35 wherein introducing the variation in pulse repetition frequency into the drive signal includes introducing a random variation in pulse repetition frequency into the drive signal.

Example 39. The method of Example 35 wherein introducing the variation in pulse repetition frequency into the drive signal includes introducing a variation in pulse repetition frequency that is at least two orders of magnitude less than the nominal pulse repetition frequency.

Example 40. The method of Example 35 wherein introducing the variation in pulse repetition frequency into the drive signal includes introducing a variation in pulse repetition frequency via a gate generator of the ultrasound system.

Example 41. The method of Example 35, further comprising: directing an ultrasound signal emitted by the at least one ultrasound transducer toward a portion of bodily tissue containing a marker, the maker comprising a hydrogel and a plurality of ultrasound reflective elements carried by the hydrogel.

Example 42. The method of any of Examples 35 through 41, further comprising:

directing an ultrasound signal emitted by the at least one ultrasound transducer toward a portion of bodily tissue containing a marker includes directing an ultrasound signal emitted by the at least one ultrasound transducer toward a portion of bodily tissue containing a marker, the maker comprising a hydrogel and a plurality of ultrasound reflective elements carried by the hydrogel.

Example 43. The method of any of Examples 35 through 41, further comprising:

directing an ultrasound signal emitted by the at least one ultrasound transducer toward a portion of bodily tissue containing a marker, the maker comprising an at least partially cross-linked hydrogel and a plurality of hollow shells at least temporarily encased by the at least partially cross-linked hydrogel, each of the hollow shells having a respective outer wall that forms a cavity, the outer wall having an irregular outer surface, and the cavity devoid of perfluorocarbon.

Example 44. The method of any of Examples 35 through 43 wherein introducing a variation in a pulse repetition frequency of the drive signal with respect to the nominal pulse repetition frequency includes introducing a variation in the pulse repetition frequency over a plurality of pulses emitted during a Doppler mode of operation during capture of one or more Doppler frames of ultrasound data.

Example 45. A marker, comprising:

at least one hollow shell having at least one outer wall that forms a cavity, the cavity devoid of perfluorocarbon.

Example 46. The marker of Example 45 wherein the cavity of the at least one hollow shell contains a gas.

Example 47. The marker of Example 45 wherein the cavity of the at least one hollow shell contains air.

Example 48. The marker of Example 45 wherein the cavity of the at least one hollow shell contains an inert gas.

Example 49. The marker of Example 45 wherein the at least one hollow shell comprises a silica.

Example 50. The marker of Example 45 wherein the at least one hollow shell consists of a silica.

Example 51. The marker of Example 45 wherein the at least one hollow shell is porous.

Example 52. The marker of Example 51 wherein the at least one hollow shell comprises a hydrophobic coating that at least temporarily seals one or more pores thereof.

Example 53. The marker of Example 45 wherein the at least one hollow shell comprises a plurality of hollow shells.

Example 54. The marker of Example 53, further comprising:

a hydrogel that binds the plurality of hollow shells together.

Example 55. The marker of Example 54 wherein the hydrogel is an at least partially cross-linked hydrogel.

Example 56. The marker of any of Examples 50 or 55 wherein the hydrogel is a gelatin.

Example 57. The marker of any of Examples 45 through 55 wherein the hollow shell has a rough outer surface.

Example 58. The marker of any of Examples 45 through 55 wherein the hollow shell is highly reflective of ultrasound.

Example 59. The marker of any of Examples 45 through 55 wherein the hollow shell has a rough outer surface and the hollow shell is highly reflective of ultrasound.

Example 60. A marker, comprising:

-   -   a hydrogel carrier; and     -   a plurality of ultrasound reflective elements carried by the         hydrogel carrier, the ultrasound reflective elements having a         high reflectivity of ultrasound, an irregular outer surface, and         being solid particles or porous and non-spherical particles.

Example 61. The marker of Example 60 wherein the hydrogel carrier binds the plurality of ultrasound reflective elements together.

Example 62. The marker of Example 61 wherein the hydrogel carrier is an at least partially cross-linked hydrogel.

Example 63. The marker of any of Examples 61 or 62 wherein the hydrogel carrier comprises a gelatin.

Example 64. The marker of any of Examples 61 or 62 wherein each of the ultrasound reflective elements of the plurality of ultrasound reflective elements comprises a respective hollow shell having at least one outer wall that forms a cavity, the cavity devoid of perfluorocarbon.

Example 65. The marker of Example 60 wherein the cavity of the hollow shell contains a gas.

Example 66. The marker of Example 60 wherein the cavity of the hollow shell contains air.

Example 67. The marker of Example 60 wherein the cavity of the hollow shell contains an inert gas.

Example 68. The marker of Example 60 wherein the hollow shell comprises a silica.

Example 69. The marker of Example 60 wherein the hollow shell consists of a silica.

Example 70. The marker of Example 60 wherein the hollow shell is porous.

Example 71. The marker of Example 60 wherein each of the ultrasound reflective elements of the plurality of ultrasound reflective elements comprises a respective a hydrophobic coating that at least temporarily seals one or more pores thereof.

Example 72. The marker of any of Examples 60 through 62 or

Examples 64 through 71 wherein the hollow shell has a rough outer surface.

Example 73. The marker of any of Examples 60 through 62 or Examples 64 through 71 wherein the hollow shell is highly reflective of ultrasound.

Example 74. The marker of any of Examples 60 through 62 or Examples 64 through 71 wherein the hollow shell has a rough outer surface and the hollow shell is highly reflective of ultrasound.

Example 75. A kit, comprising:

at least one marker, the at least one marker comprising: a plurality of hollow shells having at least one outer wall that forms a cavity, and a hydrogel that binds the plurality of hollow shells together; and

an ultrasound system, the ultrasound system comprising: at least one ultrasound transducer, and a control system including at least one drive circuit, that in operation: generates a drive signal having a nominal pulse repetition frequency; introduces a variation from the nominal frequency into the drive signal; and causes the at least one ultrasound transducer to emit an ultrasound signal having a varied pulse repetition frequency, the varied pulse repetition frequency representing the variation from the nominal pulse repetition frequency.

Example 76. The kit of Example 75 wherein to introduce a variation from the nominal frequency into the drive signal the control system introduce a variation from a nominal pulse repetition frequency into the drive signal over a plurality of pulses emitted during a Doppler mode of operation during capture of a Doppler frame of ultrasound data.

Example 77. The kit of Example 75 wherein the cavities of the hollow shells contain a gas.

Example 78. The kit of Example 75 wherein the cavities of the hollow shells contain air and are devoid of perfluorocarbon.

Example 79. The kit of Example 75 wherein the hollow shells comprise a silica.

Example 80. The kit of Example 75 wherein the hollow shells consist of a silica.

Example 81. The kit of Example 75 wherein the hollow shells are porous.

Example 82. The kit of Example 76 wherein the hollow shells each bear a hydrophobic coating that at least temporarily seals one or more pores thereof.

Example 83. The kit of Example 77 wherein the hydrogel is an at least partially cross-linked hydrogel.

Example 84. The kit of any of Examples 82 or 83 wherein the hydrogel is a gelatin.

Example 85. The kit of any of Examples 75 through 83 wherein the hollow shell has a rough outer surface.

Example 86. The kit of any of Examples 75 through 83 wherein the hollow shell is highly reflective of ultrasound.

Example 87. The kit of any of Examples 75 through 83 wherein the hollow shell has a rough outer surface and the hollow shell is highly reflective of ultrasound.

Example 88. The kit of any of Examples 75 through 83 wherein to introduce a variation from the nominal frequency into the drive signal the control system introduces a variation from a variation from a nominal pulse repetition frequency into the drive signal.

The foregoing detailed description has set forth various implementations of the devices and/or processes via the use of block diagrams, schematics, and examples. Insofar as such block diagrams, schematics, and examples contain one or more functions and/or operations, it will be understood by those skilled in the art that each function and/or operation within such block diagrams, flowcharts, or examples can be implemented, individually and/or collectively, by a wide range of hardware, software, firmware, or virtually any combination thereof. In one implementation, the present subject matter may be implemented via Application Specific Integrated Circuits (ASICs). However, those skilled in the art will recognize that the implementations disclosed herein, in whole or in part, can be equivalently implemented in standard integrated circuits, as one or more computer programs running on one or more computers (e.g., as one or more programs running on one or more computer systems), as one or more programs running on one or more controllers (e.g., microcontrollers) as one or more programs running on one or more processors (e.g., microprocessors), as firmware, or as virtually any combination thereof, and that designing the circuitry and/or writing the code for the software and or firmware would be well within the skill of one of ordinary skill in the art in light of this disclosure.

Those of skill in the art will recognize that many of the methods or algorithms set out herein may employ additional acts, may omit some acts, and/or may execute acts in a different order than specified.

In addition, those skilled in the art will appreciate that the mechanisms taught herein are capable of being distributed as a program product in a variety of forms, and that an illustrative implementation applies equally regardless of the particular type of signal bearing media used to actually carry out the distribution. Examples of signal bearing media include, but are not limited to, the following: recordable type media such as floppy disks, hard disk drives, CD ROMs, digital tape, and computer memory.

The various implementations described above can be combined to provide further implementations. U.S. patent application 60/955,678; U.S. patent application 61/034,468; U.S. patent application Ser. No. 12/673,224 (now U.S. Pat. No. 8,440,229); International patent application PCT/US2008/072972; U.S. patent application Ser. No. 13/866,940 (now U.S. Pat. No. 9,220,685); U.S. patent application Ser. No. 15/722,436; U.S. patent application 61/707,794; International patent application PCT/US2013/062436; U.S. patent application Ser. No. 15/706,446; U.S. patent application 62/135,653; U.S. patent application Ser. No. 15/559,764; International patent application PCT/US2016/23492; U.S. patent application 62/483,274; U.S. patent application 62/645,677; U.S. patent application Ser. No. 15/946,479; International patent application PCT/US2018/26291; and U.S. patent application 62/892,952, are each incorporated herein by reference in their entirety. Aspects of the implementations can be modified, if necessary, to employ systems, circuits and concepts of the various patents, applications and publications to provide yet further implementations.

These and other changes can be made to the implementations in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific implementations disclosed in the specification and the claims, but should be construed to include all possible implementations along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure. 

1. A method of operation in an ultrasound system, the method comprising: generating a clock signal having a nominal frequency; introducing a variation from the nominal frequency into the clock signal; driving at least one ultrasound transducer based at least in part on the clock signal with the introduced variation to cause the at least one ultrasound transducer to emit a plurality of ultrasound signals having at least one nonlinear variation therebetween; receiving a plurality of return signals via the at least one ultrasound transducer; match filtering the received return signals; and quadrature processing an output of the match filtering.
 2. The method of claim 1 wherein introducing the variation into the clock signal is in addition to any variation resulting from clock jitter, if any, of a master oscillator.
 3. The method of claim 2 wherein introducing the variation into the clock signal includes introducing a defined variation in pulse repetition frequency into the clock signal.
 4. The method of claim 3 wherein introducing a defined variation into the clock signal includes introducing a defined variation in at least one of: frequency, time or phase that changes over time in a defined pattern into the clock signal.
 5. The method of claim 2 wherein introducing the variation into the clock signal includes introducing a random variation in at least one of frequency, time of phase into the clock signal.
 6. The method of claim 2 wherein introducing the variation into the clock signal includes introducing a delay into the clock signal by a delay circuit.
 7. The method of claim 1 wherein introducing a variation into the clock signal includes introducing a variation that is at least one order of magnitude less than a nominal frequency of the clock signal.
 8. The method of claim 1 wherein introducing a variation into the drive clock signal includes introducing a variation that is at least two orders of magnitude less than a nominal frequency of the clock signal. 9.-13. (canceled)
 14. An ultrasound system, the comprising: at least one ultrasound transducer; a control system including at least one drive circuit, that in operation: generates a drive clock having a nominal pulse repetition frequency; introduces a variation into the clock signal; and causes the at least one ultrasound transducer to emit an ultrasound signal based at least in part on the clock signal with the introduced variation.
 15. The ultrasound system of claim 14 wherein the variation introduced into the clock signal is in addition to any variation resulting from clock jitter, if any, of a master oscillator.
 16. The ultrasound system of claim 14 wherein to introduce the variation into the clock signal the control system introduces a defined variation into the clock signal.
 17. The ultrasound system of claim 14 wherein to introduce a defined variation into the clock signal the control system introduces a defined variation in at least one of: frequency, time or phase that changes over time in a defined pattern into the clock signal.
 18. The ultrasound system of claim 14 wherein to introduce the variation into the clock signal the control system introduces a random variation in at least one of: frequency, time or phase into the clock signal.
 19. The ultrasound system of claim 14 wherein to introduce the variation into the clock signal a delay circuit introduces a delay into the clock signal.
 20. The ultrasound system of claim 14 wherein to introduce a variation into the clock signal, the at least one drive circuit introduces a variation that is at least one order of magnitude less than a nominal frequency of the clock signala.
 21. The ultrasound system of claim 14 wherein to introduce a variation into the clock signal, the at least one drive circuit introduces a variation that is at least two orders of magnitude less than a nominal frequency of the clock signal. 22.-88. (canceled)
 89. The method of claim 1 wherein quadrature processing an output of the match filtering includes quadrature sampling the output of the match filtering via a set of mixers, where one of the mixers is delayed relative to another one of the mixers.
 90. The method of claim 1 wherein quadrature processing an output of the match filtering includes phase shifting one signal path from the output of the match filtering.
 91. The method of claim 1, further comprising: down sampling an I/Q signal where the I/Q signal provides a direct representation and a quadrature representation of the match filtered return signals; and computing a phase of the down sampled I/Q signal is computed for each of a number of sample points.
 92. The method of claim 1, further comprising: down sampling an I/Q signal where the I/Q signal provides a direct representation and a quadrature representation of the match filtered return signals; and computing an amplitude of the down sampled I/Q signal is computed for each of a number of sample points. 